DE3203842A1 - METHOD AND DEVICE FOR SEPARATING SOLID AND / OR LIQUID PARTICLES FROM GASES OR. OF SOLIDS FROM LIQUIDS AND FOR THE SEPARATION OF GASES OR. LIQUIDS OF DIFFERENT DENSITY - Google Patents

Abstract

A process for the separation of solid and/or liquid particles from gases or solids from liquids, as well as for the separation of gases or liquids with different densities is proposed, in which a Venturi tube is used. The gas and/or liquid mixture is introduced inwards in radially symmetrical manner from the outside through the slot of an annular nozzle at a high flow velocity which, in the case of gases, extends up to the velocity of sound. The gas is subject to the action of a high centrifugal acceleration in the slot, which has a radius of curvature of approximately 1 to 100 mm.

Description

Method and device for separating solid and / or liquid particles from gases or solids from liquids as well as for the separation of gases or Liquids of different densities

The invention is based on a method for separating solid and / or liquid Particles from gases or solids from liquids and for separating gases or liquids of different densities according to the generic type of the main claim.

It is known to mix gas and liquid using centrifugal acceleration

^{ου separate} in cyclones and centrifuges. Furthermore, the separation nozzle method in a curved gap is known for isotope separation, particularly in the case of uranium enrichment. This method has the disadvantage that by

the two used in the process

Cleavage ends a cross flow occurs, which leads to disturbances and comparatively high energies are required.

The invention is therefore based on the object of a method and a device for Separation of solid and / or liquid particles from gases or solids from liquids as well as for the separation of gases or liquids of different To create density, thus ensuring a good separation of the different fractions with simple Funds is guaranteed.

The method and the device according to the invention have the advantage that, due to the radially symmetrical arrangement of the annular nozzle, the two that cause disturbances Column ends can be omitted. Due to the curvature in the inlet used in the invention Venturi nozzles are only slightly detached, which improves segregation and the energy losses are reduced.

By the specified in the subclaims

^iJ measures, advantageous developments and improvements are possible. A very large part of the compression energy can be recovered in the flow-optimized diffusers, so that the total energy consumption

for separation is decreased. Due to the possibility of injecting liquids the separation can be favored and the abrasion of the nozzle is considerably reduced. In addition, the liquid is used for cooling.

Furthermore, the inventive method and the device offer the advantage that they at a variety of separation processes can be used. So it is possible to collect fine dust also to separate from hot gases what is necessary for the gas treatment of gas turbines is because these require a high degree of purity of the gases. Energy losses due to the cooling of gases and their purification can therefore be bypassed. The method according to the invention can be used in the isotope separation, in particular be used in the uranium enrichment, and the so far very energy-consuming separation nozzle process peel off. Since the process according to the invention also includes water from pyrolysis gases can be a key problem in pyrolysis, namely disposal the smoldering waters, to be solved. It is also possible to separate sulfur dioxide from flue gases, Carry out selective scrubbing of gas components from gas mixtures, oils to separate from water and sediments from wastewater and a compact gas cooling system To carry out injection of liquids,

nc ■>

^itJ without droplets of liquid being entrained.

The method and the device according to the invention are to be understood with the aid of the drawing and

will be explained in more detail in the following description. Show it:

Fig. 1 shows a first embodiment

example of the device according to the invention, in which the diffusers into each other in the same

Direction of flow arranged are ;

Fi.g 2 a second embodiment of the invention

according to the device, in which the diffusers in the opposite direction are arranged; 15th

3 shows the device according to the invention, which is built into a cyclone; and

* 0 Fig. 4 a combination of the he

inventive device with a recuperator.

In the nc shown in section in FIG

Embodiment 101 denotes a rotationally symmetrical nozzle feed. the Feed 101 merges into an annular nozzle. Rotationally symmetrical about the central axis around is a diffuser 104 for the

heavy fraction and a diffuser 105 is provided for the light fraction, the Diffuser 105 for the light fraction around the diffuser 104 for the heavy fraction is arranged. The gap of the nozzle 100 is through the nozzle bottom 102 and through the

Diffuser widening towards the lower end

105 formed, the nozzle bottom 102 having an annular deflection 106 which is shown in FIG a cone tip 103 passes over. The diffuser 105 closes at its lower end a rounded part 107 and forms the inner curvature limit of the nozzle gap, while the annular deflection

106 of the nozzle bottom 102 the outer curvature limit forms. The cone tip 103 protrudes into the diffuser 104 for the heavy fraction. The flow cross-section of the nozzle 100 decreases from the outside to the outside

inside continuously.
15th

The mode of operation of the device shown in FIG. 1 is as follows: The dust or aerosol-laden gas, the gas mixture or the liquid mixtures pass through the ^xw nozzle feed 101 into the annular nozzle 100, where they are deflected by 180 ° at high speeds. The flow through the nozzle takes place from the outside to the inside, as this results in a

maximum radial acceleration is achieved.

The nozzle should have its smallest flow cross-section in the area of the greatest radial acceleration. Because of the high speed there is a segregation of the different fractions. In the area of the strongest separation of the mixtures takes place a peeling off of the fractions of different densities at the lower end of the diffuser 104 and the light fraction is through the diffuser 105 and the heavy fraction is means

of the diffuser 104 forwarded. The diffusers are shaped in such a way that the flow resistance can be kept low. The one protruding into the diffuser 104 Cone tip 103 enables the heavy fraction to be diffused with little breakage. The respective Fractions are relaxed in the diffusers 104,105, whereby a large part of the previously Applied compression energy can be recovered.

In Fig. 2 is a section through a further embodiment is shown in which Identical and identically acting parts are denoted by the same reference numerals as in FIG. 1 are. The difference to the embodiment of FIG. 1 is that the diffusers 104 and 105 are not one inside the other are arranged in the same direction of flow, but opposite. The diffuser 104 for the heavy fraction is arranged downwards here. To guide the components the heavy fraction, an annular deflecting part 203 is provided, which is attached to

takes the place of the cone tip 103. The peeling of the different densities Fractions now take place at this deflection part 203. A bypass system 208 can Components of the heavy fraction in the

Be fed back to the nozzle. The mode of operation is the same as that described above.

To the separation of the different factions

can be improved between the nozzle bottom 35

and the diffuser 105, which with its rounded

Part 107 at the same time as an inner curvature limit of the gap is used,. an electric field can be applied.

In the case of gas mixtures, liquids can additionally be injected into the nozzle feed 101 which improves the separation of solids from the gases. In addition, the liquids are used for washing, cooling and reducing abrasion the nozzle, which significantly increases its service life. The liquids can then separated with the heavy fraction as shown in FIG.

3 shows the use of the device according to the invention in a cyclone 300. This arrangement is a particularly advantageous combination because of the coarse components in the cyclone and the fine components in the annular nozzle 100 can be separated. This is done accordingly the mode of action described above. This arrangement still brings the special one

* ° The advantage that already existing cyclones can be converted by installing the device according to the invention.

The device 400 shown in FIG. 4

shows the combination of the annular nozzle according to the invention with a conical one Recuperator 401. In this embodiment, the hot flue gases enter the Feed 402 and flow radially symmetrically along the conical walls of the recuperator to the outside.

Coarser components can be separated by a deflection 403. The pre-cleaned Gases then flow inwards again in a radially symmetrical manner along a conical surface, whereby the flow velocity increases due to the narrowing of the cross section. in the Inside there is a deflection by 180 °. A peeling device 405 makes another Separated dust fraction. This fraction becomes a separate one via a diffuser 406 Separator system out and then returned via a bypass. After this first peeling the gas is passed to a cone-shaped heat exchanger 407 and then to the outside

• 5 led back inwards, to then correspondingly Fig. 1 to be finely cleaned in the final annular nozzle 100.

The heat exchanger 407 need not be conical

^{ζυ be} trained. A plane-parallel surface exchanger can also be used which, however, is also flowed around in the radial direction from the inside to the outside and from the outside to the inside, the deflection in the interior at a high rate

Radial accelerations favor peeling. However, it can be structurally easier, two-dimensional arrangement with hot gases warped very easily. In the case of the conical Arrangement lead to temperature stresses only to a change in the cone angle, which is structurally can be caught very easily.

Claims (14)

^ Claims 1. Process for the separation of solid and / or liquid particles from gases or solids from liquids as well as for the separation of gases or liquids of different densities using a venturi, thereby marked that the ^ O gas and / or liquid mixture with Flow velocities that approach the speed of sound for gases, Radially symmetrical from the outside through the gap of an annular nozzle inwards '^; and in the gap with a Radius of curvature of approx. 1 to 100 mm subjected to a high centrifugal acceleration will. 2. Device for carrying out the method according to claim 1 with a feed for the gas or the liquid and with outlets for the separate factions, thereby characterized in that the gap of the annular Nozzle (100) with a deflection angle of> 90 ° is deflected in such a way that it is both at the beginning and at the end of the deflection is arranged around the central axis of the annular nozzle, in the direction of flow the diameter of the gap, calculated from the central axis, becomes smaller. 3. Apparatus according to claim 2, characterized in that to reduce detachments of the flowing medium in the curvature of the flow cross-section in the curvature area continuously decreased in the direction of flow up to the area of separation of the fractions. 4. Apparatus according to claim 2 or 3, characterized in that the annular nozzle (100) is designed such that it is in the region of the highest radial acceleration has the smallest flow cross-section. 5. Device according to one of claims 2 to 4, characterized in that im Area of the strongest separation of the fractions an arrangement for peeling off the different dense fractions is provided. 6. Device according to one of claims 2 to 5, characterized in that for forwarding of the separated fractions at least two diffusers (104, 105) are provided. 7. Apparatus according to claim 6, characterized in that the diffusers (104,105) in are arranged one inside the other in the same direction of flow. 8. Apparatus according to claim 7, characterized in that in the inner diffusers (104) a cone (103) protrudes axially for the heavy fraction. • 9. Apparatus according to claim 6, characterized in that that the diffusers (104,105) are arranged in the opposite direction are, wherein a deflection part (203) is provided for deflecting the heavy fraction is, which also serves as an arrangement for peeling. I - 10. Device according to one of claims 2 to 9, ^ O characterized in that for recovery of compression energy, the diffusers (104,105) are designed such that the separated fractions can relax.
15th 11. Device according to one of claims 2 to 10, characterized in that it is in a recuperator is integrated. 12. Device according to one of claims 2 to 10, characterized in that it is with combined with a cyclone. 13. Device according to one of claims 2 to 12, characterized in that to improve the separation of the fractions an electric field is applied between the delimiting curved surfaces. 14. The method according to claim 1, characterized in that before the separation in the case of gas mixtures Liquids are injected with the heavy fractions separated be oc.